Nanoparticle-Templated Assembly of Viral Protein Cages

Chen, Chao; Daniel, Marie‐Christine; Quinkert, Zachary T.; De, Mrinmoy; Stein, Barry D.; Bowman, Valorie D.; Chipman, Paul R.; Rotello, Vincent M.; Kao, C. Cheng; Dragnea, Bogdan

doi:10.1021/nl0600878

Cited by 217 publications

(271 citation statements)

References 15 publications

Supporting

Mentioning

266

Contrasting

Unclassified

Order By: Relevance

“…The most widely used biological template for directed AuNP assemblies is DNA 21,22 , but also peptide fibrils 23 or protein fibres 2 were deployed as templates, for example, amyloid fibres for the construction of conducting nanowires 2 . Another prominent example for proteinaceous assemblies is the patterning or encapsulation of metal NPs by virus capsids [24][25][26] . The great advantage of protein-based assemblies is the ability to store and tune information about precise structure, composition and interaction potential on the genetic level.…”

mentioning

confidence: 99%

Molecular protein adaptor with genetically encoded interaction sites guiding the hierarchical assembly of plasmonically active nanoparticle architectures

et al. 2015

View full text Add to dashboard Cite

The control over the defined assembly of nano-objects with nm-precision is important to create systems and materials with enhanced properties, for example, metamaterials. In nature, the precise assembly of inorganic nano-objects with unique features, for example, magnetosomes, is accomplished by efficient and reliable recognition schemes involving protein effectors. Here we present a molecular approach using protein-based 'adaptors/ connectors' with genetically encoded interaction sites to guide the assembly and functionality of different plasmonically active gold nanoparticle architectures (AuNP). The interaction of the defined geometricaly shaped protein adaptors with the AuNP induces the self-assembly of nanoarchitectures ranging from AuNP encapsulation to one-dimensional chain-like structures, complex networks and stars. Synthetic biology and bionanotechnology are applied to co-translationally encode unnatural amino acids as additional site-specific modification sites to generate functionalized biohybrid nanoarchitectures. This protein adaptor-based nanoobject assembly approach might be expanded to other inorganic nano-objects creating biohybrid materials with unique electronic, photonic, plasmonic and magnetic properties.

show abstract

mentioning

confidence: 99%

Molecular protein adaptor with genetically encoded interaction sites guiding the hierarchical assembly of plasmonically active nanoparticle architectures

et al. 2015

View full text Add to dashboard Cite

show abstract

“…metamaterials ͉ protein cage ͉ self-assembly ͉ surface plasmon ͉ virus assembly E ngineered virus capsids and protein cage structures have shown increasing promise as therapeutic and diagnostic vectors (1-6), imaging agents (7-10), and as templates and microreactors for advanced nanomaterials synthesis (11)(12)(13)(14)(15)(16)(17). Here, we address the rules for the formation of symmetric protein cages consisting of viral capsid subunits formed over a functionalized inorganic nanoparticle core, called virus-like particles (VLPs).VLPs provide an example of how biomimetic self-organization can combine the natural characteristics of virus capsids with the exquisite physical properties of nanoparticles (18)(19)(20). Interactions between the artificial cargo and the protein carrier affects both the self-assembly and the stability of the resulting structure, yet very little is known about them.…”

mentioning

confidence: 99%

“…VLPs provide an example of how biomimetic self-organization can combine the natural characteristics of virus capsids with the exquisite physical properties of nanoparticles (18)(19)(20). Interactions between the artificial cargo and the protein carrier affects both the self-assembly and the stability of the resulting structure, yet very little is known about them.…”

mentioning

confidence: 99%

“…We have determined that a gold core functionalized with a coating of carboxylated polyethylene glycol (PEG) can allow efficient assembly of VLPs (18). Here, we report some first steps in a systematic examination of how these cores influence the capsid structures and functional properties.…”

mentioning

confidence: 99%

“…When gold particles are absent from the assembly mixture, a larger number of empty capsids are observed in TEM micrographs than in the presence of Au (18). Incorporation of gold nanoparticles is therefore the result of the competition between the formation of empty capsids and other aggregates and VLPs.…”

mentioning

confidence: 99%

See 2 more Smart Citations

Core-controlled polymorphism in virus-like particles

Sun

Dufort²,

Daniel³

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

272

363

View full text Add to dashboard Cite

This study concerns the self-assembly of virus-like particles (VLPs) composed of an icosahedral virus protein coat encapsulating a functionalized spherical nanoparticle core. The recent development of efficient methods for VLP self-assembly has opened the way to structural studies. Using electron microscopy with image reconstruction, the structures of several VLPs obtained from brome mosaic virus capsid proteins and gold nanoparticles were elucidated. Varying the gold core diameter provides control over the capsid structure. The number of subunits required for a complete capsid increases with the core diameter. The packaging efficiency is a function of the number of capsid protein subunits per gold nanoparticle. VLPs of varying diameters were found to resemble to three classes of viral particles found in cells (T ‫؍‬ 1, 2, and 3). As a consequence of their regularity, VLPs form three-dimensional crystals under the same conditions as the wild-type virus. The crystals represent a form of metallodielectric material that exhibits optical properties influenced by multipolar plasmonic coupling. metamaterials ͉ protein cage ͉ self-assembly ͉ surface plasmon ͉ virus assembly E ngineered virus capsids and protein cage structures have shown increasing promise as therapeutic and diagnostic vectors (1-6), imaging agents (7-10), and as templates and microreactors for advanced nanomaterials synthesis (11)(12)(13)(14)(15)(16)(17). Here, we address the rules for the formation of symmetric protein cages consisting of viral capsid subunits formed over a functionalized inorganic nanoparticle core, called virus-like particles (VLPs).VLPs provide an example of how biomimetic self-organization can combine the natural characteristics of virus capsids with the exquisite physical properties of nanoparticles (18)(19)(20). Interactions between the artificial cargo and the protein carrier affects both the self-assembly and the stability of the resulting structure, yet very little is known about them. Progress toward the basic development and the practical use of VLPs requires an understanding of how relevant parameters contribute to complex formation.Symmetric VLPs may provide a technology for therapeutic or diagnostic agent delivery that is improved over amorphous shell nanoparticles that are already known to be efficient in similar applications (21). The advantage of a regular surface protein motif is that the binding domains are functionally identical by virtue of their equivalent environment. It has been shown in several situations that receptor-mediated targeting can be achieved even when using amorphous coatings (22). However, the principle challenges for nanoparticle delivery currently include: limited life-time in body fluids, nanoparticle transduction across the cellular membrane, avoidance of the exocytotic pathways, and target specificity. To optimize their infectivity, viruses have evolved to overcome these challenges. We still must learn how to apply virus strategies to targeted delivery. A simple question is central to this o...

show abstract

Inorganic Nanocrystals: Patterning and Assembling

Curri

Comparelli

Striccoli

et al. 2005

Encyclopedia of Inorganic Chemistry

View full text Add to dashboard Cite

Recently, increasing interest has been devoted to the study of the size‐dependent properties of inorganic nanocrystals and nanoparticles, in order to investigate and exploit their original potential. The ability to access nanoparticle properties for device fabrication is based on their organization in morphologically controlled assembly and/or ordered arrays, with suitable patterning, in order to bridge the gap between nanoscopic and mesoscopic scale. Assembly procedures allow the formation of original ordered state of matter and the fabrication of 2‐/3‐D patterned micro‐ and nanostructure, representing a promising route for producing functional materials and for processing and integrating the nanoparticles in macroscopic systems to fully develop their unprecedented functionality for materials and devices for biomedical, electronic, catalytic, and separation process technologies. Top‐down technological methods and techniques, conventional and emerging, have been cleverly and ingenuously combined and matched with dedicated bottom‐up approaches, paying attention to the peculiarity of the nanoparticle size regime. In most approaches, a precise control on the size and shape of the nanoparticles is crucial for driving the assembling and the extent to which the building blocks can be engineered, designed, and fabricated with desired features, including encoded instructions for assembling, has been greatly progressing in the last years. This article focuses on the potential of exploitation of inorganic nanocrystals and nanoparticles for assembling. An overview of the inorganic nanocrystal functions in the different and complementary strategies is outlined, highlighting the novelty and originality of the specific results and placing them in the scenario of the emerging material science, toward the envisioned creation of materials by design.

show abstract

Nanoparticle-Templated Assembly of Viral Protein Cages

Cited by 217 publications

References 15 publications

Molecular protein adaptor with genetically encoded interaction sites guiding the hierarchical assembly of plasmonically active nanoparticle architectures

Molecular protein adaptor with genetically encoded interaction sites guiding the hierarchical assembly of plasmonically active nanoparticle architectures

Core-controlled polymorphism in virus-like particles

Inorganic Nanocrystals: Patterning and Assembling

Contact Info

Product

Resources

About